a vision for nsf earth sciences 2020-2030: earth in time
TRANSCRIPT
A Vision for NSF Earth Sciences 2020-2030:Earth in Time
Jim Yoder, Greg Beroza, Andrea Dutton, Michael Foote,George Gehrels, Kate Huntington, Donna Whitney, and the Committee
on Catalyzing Opportunities for Research in the Earth Sciences
May 19, 2020
NSF Organization
Statement of TaskNASEM will help provide advice that EAR can use to set priorities and strategies for its investments on research, infrastructure, and training in the coming decade. The report will include:
1. A concise set of high-priority scientific questions that will be central to the advancement of Earth sciences over the coming decade and could help to transform our scientific understanding of the Earth.
2. (A) Identification of the infrastructure needed to advance the high-priority Earth science research questions from task #1, (B) discussion of the current inventory of research infrastructure supported by EAR and other relevant areas of NSF, and (C) analysis of capability gaps that would need to be addressed in order to align B with A.
3. A discussion of how EAR can leverage and complement the capabilities, expertise, and strategic plans of its partners (including other NSF units, federal agencies, domestic and international partners), encourage greater collaboration, and maximize shared use of research assets and data.
The ad hoc committee will consider these tasks within the context of the present EAR budget.
In addition, the National Academies convened a workshop to address different management models for future seismological and geodetic facility capabilities, providing additional information for Task 2 of the CORES study.
Statement of Task, cont.
Greg Beroza, Stanford University
Tanja Bosak, Massachusetts Institute of Technology
Bill Dietrich, University of California, Berkeley
Tim Dixon, University of South Florida
Andrea Dutton, University of Wisconsin–Madison
Diana Elder, Northern Arizona University (resigned)
Lejo Flores, Boise State University
Michael Foote, University of Chicago
Shemin Ge, University of Colorado Boulder
George Gehrels, University of Arizona
Doug Hollett, Melroy-Hollett Technology Partners
Bruce Houghton, University of Hawaii at Manoa
Kate Huntington, University of Washington
Steve Jacobsen, Northwestern University
Dennis Kent, Rutgers University
Carolina Lithgow-Bertelloni, University of California, Los AngelesPaul Olsen, Columbia University
Don Sparks, University of Delaware
Donna Whitney, University of Minnesota
Committee RosterJim Yoder (Chair), Woods Hole Oceanographic Institution
• Vision• Science priority questions• Infrastructure & initiatives• Partnerships
Outline
• EAR can enhance support for Earth research as an integrated system
Vision
• This is an “all hands on deck” moment; we need– Diverse, inclusive groups– Individuals, teams, and collaborative networks– Cutting-edge analytical, computational, and field-based methods
Information-gathering– Literature review– Community input
questionnaire– Listening sessions/town halls– Workshops held previously
by community groups– Interviews with colleagues– Invited discussions during
committee meetings
Developing priorities– Generating “long list”– Merging similar questions– Examining the scientific
importance and likelihood of transformative impact
– Framing the questions
Science Priorities – Approach
Identify specific questions that are poised for major advances in next 10 years
Some questions have long been of great interest
A. Dutton
Field gear.
Integrating Themes• Earth system components interact
over time and space
• Connections between Earth spheres increasingly important
• Technological advances enable new observations and modeling
• Societal relevance of fundamental Earth science research
Science Priorities
• Key insights come from a strong disciplinary research program
• There will be unanticipated discoveries with profound effects
D. Zwartz
Person conducting fieldwork.
• How is Earth’s internal magnetic field generated?
• When, why, and how did plate tectonics start?
• How are critical elements distributed and cycled in the Earth?
•
• What is an earthquake?
• What drives volcanism?
• What are the causes and consequences of topographic change?
• How does the critical zone influence climate?
• What does Earth’s past reveal about the dynamics of the climate system?
•
• How is Earth’s water cycle changing?•
• How do biogeochemical cycles evolve?
• How do geological processes influence biodiversity?
• How can Earth science research reduce the risk and toll of geohazards?
Science Priority Questions
• How is Earth’s internal magnetic field generated?
• Understanding what has powered the geodynamo through time and what controls its rate of change is crucial for understanding interactions from Earth’s interior to the atmosphere.
Magnetic field lines stretched by turbulent core flow
Julien Aubert, IPGP/CNRS
• When, why, and how did plate tectonics start?
Plate tectonics produce and modify continents, oceans, and atmosphere, but we don’t yet understand when it developed, why Earth has plate tectonics, and how it developed.
Tomographic modeling shows the map view underneath North America
Bozdağ et al., 2016
Element cycling creates suitable conditions for life and ingredients for materials needed for modern civilization, yet questions remain about how elements are transported within the Earth, across many spatial & temporal scales.
• How are critical elements distributed and cycled in the Earth?
N.A. MeyerJ.W. Valley D.L. Whitney Wang et al., 2019
The redistribution and cycling of critical elements occurs from atomic to global scales over geologic time.
Atomic scale Mineral scale Rock scale Mantle scale
Deformation of the Earth occurs over a spectrum of rates and in a variety of styles, leading geoscientists to reconsider the very nature of earthquakes and their dynamics.
• What is an earthquake?
Surface rupture from the Ridgecrest earthquake
USGS
Volcanic eruptions affect people, the atmosphere, the hydrosphere, and Earth, creating an urgent need for research on how magma forms, rises, and erupts.
Halemaumaulava lake
• What drives volcanism?
B. Houghton
New technology for measuring topography over geologic to human timescales makes it possible to address Earth system interactions & urgent societal challenges.
Landscape change due to landslides triggered by earthquakes and storms in Taiwan
• What are the causes and consequences of topographic change?
Kristen L. Cook
The critical zone influences moisture, groundwater, and energy & gas exchanges between the land and atmosphere, and its influence on climate is vital to understanding how the Earth system has responded and will respond to global change.
• How does the critical zone influence climate?
Lidar-derived vegetation and surface topography at Eel River CZO.
Rempe and Dietrich, 2018
Evidence of long-term and rapid environmental change in Earth’s history helps us understand Earth system dynamics and provides magnitudes and rates of change, which are crucial for prediction.
• What does Earth’s past reveal about the dynamics of the climate system?
A. Dutton M.Morad
NOAA
Speleothem Tree ring Sediment core
• How is Earth’s water cycle changing?•
Understanding current and future changes to the water cycle requires fundamental knowledge of the hydro-terrestrial system and how the water cycle interacts with other physical, biological, and chemical processes.
Potential water cycles changes in permafrost regions under current and future warmer climate scenarios.
How do biogeochemical cycles evolve?
To quantify biology’s role through time in mineral formation and weathering, carbon cycling, and the composition of the air we breathe requires a new understanding of biogeochemical cycles.
Oxygen bubble produced by cyanobacterial photosynthesis in a laboratory-grown microbial mat
T. Bosak
• How do geological processes influence biodiversity? Biodiversity varies over time, environment, and geography, including major extinctions, and we are poised to address how and why to advance understanding of Earth-life interactions and feedbacks.
Two hypotheses regarding evolutionary relationships among the major groups
of living organisms Modified from Williams et al., 2013
Fundamental science questions must be addressed to have a predictive and quantitative understanding of geohazards, to provide the essential foundation needed to reduce risks and to save lives and infrastructure.
Debris flows smashed houses and killed people in Montecito, California, in January 2018.
• How can Earth science research reduce the risk and toll of geohazards?
USGS
• Task 2A: Describe future infrastructure needed to address science questions
• Task 2B: Describe current infrastructure and show connections to science questions
• Task 2C: Capability gaps
Facilities & Infrastructure Approach
Portion of a table showing connections between existing infrastructure and questions
• Describe available infrastructure (EAR, GEO, NSF, NASA, USGS, DOE, etc.)• Establish connections between infrastructure and science questions• Challenging to evaluate how well the needs of EAR research communities are
met– information needed to perform this type of assessment was not available
Facilities & Infrastructure Approach
Recommendation: EAR-supported facilities and the entire portfolio of EAR-supported infrastructure should be regularly evaluated using stated criteria in order to prioritize future infrastructure investments, sunset facilities as needed, and adapt to changing science priorities.
Analyzed three components of infrastructure:
Facilities & Infrastructure Approach
• Instruments
• Cyberinfrastructure
• Humans(NSF 10 Big Ideas)
DOE
G. Gehrels
Synchrotron and people in lab working.
• Originate from EAR research communities - based on questionnaire responses, community white papers, presentations in public sessions
• Funding will require either a source of new funds and/or sunsetting some current programs
Possible New Initiatives
• EAR should fund– a National Consortium for Geochronology– a Very Large Multi-Anvil Press User Facility– a Near-Surface Geophysics Center
• EAR should support continued community development of the SZ4D initiative, including the Community Network for Volcanic Eruption Response.
Recommendations for New Initiatives
• EAR should encourage the community to explore– a Continental Critical Zone initiative– a Continental Scientific Drilling initiative
• EAR should facilitate a community working group to develop mechanisms for archiving and curation of currently existing and future physical samples and for funding such efforts.
Recommendations for New Initiatives
• EAR should initiate a community-based standing committee to advise EAR regarding cyberinfrastructure needs and advances.
• EAR should develop and implement a strategy to provide support for FAIR practices within community-based data efforts.
Cyberinfrastructure Recommendations
Hand with computer code.
• EAR should commit to long-term funding that develops and sustains technical staff capacity, stability, and competitiveness.
Human Infrastructure Recommendations
• EAR should enhance its existing efforts to provide leadership, investment, and centralized guidance to improve diversity, equity, and inclusion within the Earth science community.
G. Gehrels
Lab team at the Arizona LaserchronCenter.
• A nimble EAR can quickly take advantage of the shifting frontiers in basic science and interdisciplinary research.
• Because Earth science is increasingly global, EAR-funded researchers benefit from international collaboration.
• Components of the Earth system do not adhere to the administrative boundaries of GEO.
• NASA, DOE, and USGS provide important capabilities supporting EAR research.
Partnerships Conclusions
EAR should collaborate with other GEO divisions and other agencies to fund geoscience research that crosses boundaries, such as shorelines, high latitudes, and the atmosphere–land interface.
EAR should proactively partner with other NSF divisions and other federal agencies to advance novel societally relevant research.
Partnerships Recommendations
• EAR’s mission is more important and urgent than ever• Science priority questions illustrate the significance, breadth, and
magnitude of the challenges and opportunities for Earth science research in the next decade
• Implementing cyber and human infrastructure recommendations will require not just a commitment of funding, but significant changes to “business as usual” for the community
• EAR already leads investigation of Earth as an interconnected system and is poised to launch the next decade of innovative research
Final Thoughts
Thank You